Partial table and multisource synchronization for databases

ABSTRACT

A database system provides automatic synchronization from one or more databases to a table. The synchronized portion of each source database table is periodically imported into a corresponding portion of a destination database table. For each synchronized field in the table with data from multiple source databases, one of the source databases is set as a primary source, which determines the data type and field configuration of the field. Data from secondary sources are cast to the data type established by the primary source and represented using the primary source&#39;s field configuration. The source database table may also include data that is not synchronized with the destination database table. Similarly, the destination database table may be enriched with data that is not included in the source database table.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. Non-Provisional applicationSer. No. 17/473,872, filed Sep. 13, 2021, which claims the benefit ofU.S. Provisional Application No. 63/078,295, filed Sep. 14, 2020, andU.S. Provisional Application No. 63/165,538, filed Mar. 24, 2021, eachof which is incorporated by reference.

BACKGROUND 1. Technical Field

The subject matter described relates generally to databases and, inparticular, to techniques for synchronizing data from one or moresources to a data table.

2. Background Information

Enterprises and other entities often provide different users with accesspermission to different subsets of the data available to the entity. Asa result, entities typically maintain multiple databases that includepartially overlapping data. Maintaining consistency between theoverlapping portions can be a time-consuming and error prone task. Forexample, if a human is responsible for entering new data into multipledatabases, typographical and other errors may lead to discrepanciesbetween different versions of the data. One approach to addressing thisproblem is to store the data in a single database and control whichusers have access to which records but maintaining the accesspermissions in this scenario is also a time-consuming process. Thisprocess is also subject to error. For example, human error in updatingpermissions may reveal confidential data to users who are not authorizedto access it.

Maintaining a database that includes data from several sources can beespecially time-consuming and error prone. When an attribute in thedatabase includes data taken from multiple sources, data loss can occurwhen different sources have different data types or different labels forthe attribute.

SUMMARY

The above and other problems may be addressed by a database system thatprovides automatic synchronization from one or more databases to atable. The synchronized portion of each source database table may beperiodically (e.g., once every five minutes, once an hour, etc.)imported into a corresponding portion of a destination database table.For each synchronized field in the table with data from multiple sourcedatabases, one of the source databases is set as a primary source, whichdetermines the data type and field configuration of the field. Data fromsecondary sources are cast to the data type established by the primarysource and represented using the primary source's field configuration.

The source database table may also include data that is not synchronizedwith the destination database table. Similarly, the destination databasetable may be enriched with data that is not included in the sourcedatabase table.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a networked computing environment suitablefor providing partially synchronized database tables, according to oneembodiment.

FIG. 2 is a block diagram of the server of FIG. 1, according to oneembodiment.

FIG. 3 is a block diagram of the bases data store of FIG. 2, accordingto one embodiment.

FIG. 4 illustrates multisource synchronization of three tables of threedatabases in the bases data store 210, according to one embodiment.

FIG. 5 is a flowchart of a method for partially synchronizing databasetables, according to one embodiment.

FIG. 6 illustrates a method for multisource synchronizing databasetables, according to one embodiment.

FIG. 7 is a block diagram illustrating an example of a computer suitablefor use in the networked computing environment of FIG. 1, according toone embodiment.

DETAILED DESCRIPTION

The figures and the following description describe certain embodimentsby way of illustration only. One skilled in the art will readilyrecognize from the following description that alternative embodiments ofthe structures and methods may be employed without departing from theprinciples described. Wherever practicable, similar or like referencenumbers are used in the figures to indicate similar or likefunctionality. Where elements share a common numeral followed by adifferent letter, this indicates the elements are similar or identical.A reference to the numeral alone generally refers to any one or anycombination of such elements, unless the context indicates otherwise.

The techniques described herein provide for data synchronization amongvarious data tables, whether local or external, such that the data in asynchronized data table is consistent and up to date. Synchronized datatables can be used to allow various groups of users to manage and evolvetheir databases and workflows independently, while still being able tocollaborate on shared data tables where data from various sources isaggregated. Furthermore, this may provide data synchronization withfewer transcription errors than existing approaches.

The described techniques also provide for increased data security. Forexample, synchronized tables provide for limited data visibility, whereaccess can be limited to particular users or groups. Synchronized tablesenable a user to share, on a limited basis, particular subsets of datafrom the user's database with other users, internal or external, and theuser can set, on a user-by-user or per-domain basis, read and writepermissions to the shared data in the synchronized table. As thesepermissions are set for the synchronized table, any edits to thesynchronized table do not affect the user's source table, preserving theintegrity of the user's database. A synchronized data table can be usedto expose particular up-to-date data to external users, e.g., fromdifferent organizations, with tight control over the schedule on whichthe data updates, and the ability to revoke data sharing, thus balancingcollaboration and security in interorganizational sharing.

These and other benefits can be recognized in view of the presentdisclosure.

EXAMPLE SYSTEMS

FIG. 1 illustrates one embodiment of a networked computing environment100 suitable for providing partially synchronized database tables. Inthe embodiment shown, the networked computing environment 100 includes aserver 110, an external server 115, a first client device 140A, and asecond client device 140B, all connected via a network 170. Although twoclient devices 140 are shown, the networked computing environment 100can include any number of client devices 140. Similarly, although oneexternal server 115 is shown, the networked computing environment 100can include any number of external servers 115. In other embodiments,the networked computing environment 100 includes different or additionalelements. In addition, the functions described herein may be distributedamong the elements in a different manner than described.

The server 110 hosts multiple databases and performs synchronizationbetween databases with a cross-base synchronize function. The cross-basesynchronize function copies data from a shared source view to a targettable. Data may be copied in one direction during a synchronization.When a synchronization completes, the target table contains all of therows in the source view and cell data for all columns (alternatively,“fields”) selected to be synchronized. In one embodiment, only data(rows and columns) that are explicitly or implicitly set as ‘visible’ inthe shared view can be copied. Users may determine what data isavailable to synchronize (and in what form) using a shared viewinterface (e.g., to designate one or more rows or columns as visible ornot visible). As described in further detail below, a user cansynchronize some or all data from one or more sources to a target table,and one or more of the sources can be external to the server 110, e.g.,may be hosted by an external server 115.

In an embodiment, data in the target table matches the format of thedata in the shared view interface. For example, if linked records arerendered as text in shared views, they also render as text in the targettable. Formulas may render as their result type and look like anon-formula field. As a consequence of this design, synchronization doesnot differentiate between data being deleted from the source table orsimply being hidden from the shared view. As described in further detailbelow, matching data from source to target table can follow analternative technique.

The following table illustrates the mapping between source and targetdata types for one embodiment:

Source type Target type Number/date/single-line text/long Identical typeand configuration (e.g. number/date text/rich text/select/multi-selectformatting, select color and order) Foreign key TextCollaborator/Multi-collaborator Text Lookups As the looked-up type (sosynchronizing a lookup of a foreign key will result in text)Formulas/Rollups As the result type Button fields ‘Open URL’ type buttonfields will be synchronized as URL field Attachments As-is

A synchronized target table mirrors the contents of its source view butcan contain additional unsynchronized columns to enrich the synchronizeddata. For example, one might collect T-shirt sizes for all employees bysynchronizing into the target table a list of employees and then addingan unsynchronized ‘T-shirt size’ column, where each employee enrichesthe target table by entering their T-shirt size to a respective row atthe ‘T-shirt size’ column.

In an embodiment, users of the target table are not allowed to create ordestroy records in the synchronized portion of the table, nor to changecell values or column type and type options for any synchronized column,but they can make changes to non-synchronized columns. In someembodiments, users of the target table may change the names anddescriptions for synchronized columns, which does not impact the sourcetable (i.e., source view) but changes how the synchronized data isdisplayed in the target table (e.g., a column in the target table has adifferent name than the corresponding column in the source table).

Various embodiments of the server 110 are described in greater detailbelow, with reference to FIG. 2.

The client devices 140 are computing devices with which users can accessand edit the databases managed by the server 110. Example client devicesinclude desktop computers, laptop computers, smartphones, tablets, etc.The client devices 140 may enable users to interact with the databasesvia a user interface accessed via a browser, a dedicated softwareapplication executing on the client devices, or any other suitablesoftware.

The external server 115 is a server, which may be associated with adifferent entity than the server 110. For example, server 110 isassociated with a first organization, and server 115 is associated witha second organization. The external server 115 may be, for example, aSALESFORCE server, a JIRA server, a GOOGLE CALENDAR server, or a BOXserver. Users of client devices 140 can synchronize data from sourcetables in databases hosted at the external server 115 to target tablesat the server 110. This can involve the user providing credentialinformation, which the server 110 uses to connect to the external server115.

The server 110 can synchronize data from the external server 115 to atarget table in a database of the server 110. In one embodiment, theserver 110 stores a tabular data mapping to translate data from theexternal server 115 to a usable format for server 110 databases. Theserver 110 may store a different tabular data mapping for each ofmultiple external servers 115 to facilitate data transfer to the targettable. For example, the server 110 may store a first tabular datamapping for SALESFORCE reports that uses a SALESFORCE applicationprogramming interface (API), a second tabular data mapping for JIRAissue filters that uses a JIRA API, and a third tabular data mapping forGOOGLE CALENDAR events that uses a GOOGLE CALENDAR API. Using the API ofan external server 115, the server 110 can request and receivesynchronized data for a target table. For example, the server 110 maysend a query to the external server 115 using a respective API function,where the query specifies the data to be synchronized to the targettable, and then the server 110 receives, via a different API function,query results including the synchronized data from the external server115. The server 110 identifies an external server 115, fetches therespective tabular datamapping, and uses the respective tabular datamapping to synchronize data from the external server 115 (e.g., to atarget table).

The network 170 provides the communication channels via which the otherelements of the networked computing environment 100 communicate. Thenetwork 170 can include any combination of local area and wide areanetworks, using wired or wireless communication systems. In oneembodiment, the network 170 uses standard communications technologiesand protocols. For example, the network 170 can include communicationlinks using technologies such as Ethernet, 802.11, worldwideinteroperability for microwave access (WiMAX), 3G, 4G, 5G, code divisionmultiple access (CDMA), digital subscriber line (DSL), etc. Examples ofnetworking protocols used for communicating via the network 170 includemultiprotocol label switching (MPLS), transmission controlprotocol/Internet protocol (TCP/IP), hypertext transport protocol(HTTP), simple mail transfer protocol (SMTP), and file transfer protocol(FTP). Data exchanged over the network 170 may be represented using anysuitable format, such as hypertext markup language (HTML) or extensiblemarkup language (XML). In some embodiments, all or some of thecommunication links of the network 170 may be encrypted using anysuitable technique or techniques.

Embodiments of various techniques of the networked computing environment100 will now be described. Alternative techniques may be employedwithout departing from the principles set forth herein.

A user of client device 140A can interface with the server 110 to createa synchronized target table according to one or more techniques,depending upon the embodiment. The user interface may be exposed by theserver 110 or client device 140A. In one embodiment, the user receives alink to a shared view (e.g., from an administrator of the databaseincluding the shared view). The user provides an instruction the server110 to use the link to initiate a synchronization , either with a newtable or an existing table. The server 110 sets up the requestedsynchronization between the shared view and the selected table. In oneembodiment, the user selects a widget of a user interface exposed by theserver 110 that displays a shared view to create a new synchronizedtable using the shared view.

In an embodiment, the link to the shared view may be temporary, e.g.,only useable once, or for a finite period of time, such as 24 hours.Thereafter, the source table may be identified by a source tableidentifier. In this manner, the source table can be secured, such thatif the user ends synchronization to the target table, the link cannot beused to inappropriately gain access the source table. In an embodiment,a user that shares a like to a shared view to another user may revokeaccess to the shared view from the other user.

In one embodiment, the user has access permission to the source tableand the target table. The user can create a new shared view or enablesynchronization of an already-existing shared view. The user can thenproceed with one of the above techniques. Alternatively, the user cannavigate to a user interface that displays the target table and select awidget to expose a list of potential source tables. The user can selectthe shared view to use it as a source table. In various embodiments, theuser can set a table (e.g., for which the user has access permission) asable to be synchronized (i.e., can be used as a source table) or not. Invarious embodiments, the user can designate some or all of the rows orcolumns in the table as able to be synchronized or not.

In an embodiment, the user can restrict access to the table such that itis password protected. Additionally or alternatively, the user canrestrict access to the table such that only users associated withspecified email addresses or email domains can access the table.

In one embodiment, if a source table is password-protected, the userinitiating synchronization to a target table is prompted to correctlyenter the password to the source table in order to set up thesynchronization. Once the password has been entered, synchronization mayoperate automatically, indefinitely, or for a predetermined time period(e.g., one month or one year) without requiring password reentry. If thepassword changes, or if a password is added to a previously unprotectedsource table, the synchronization stops working until authenticated orreauthenticated. In an embodiment, the user can revoke accesstemporarily or permanently.

In one embodiment, if a source table is email domain-protected, the userinitiating the synchronization needs to have a verified email with apermissioned domain in order to set up the synchronization. If theinitiating user's email address with the permissioned domain isdeactivated, suspended, or otherwise made inactive, the synchronizationmay cease to operate. Alternatively, a synchronization may remainoperational as long as any user of the target table has an email addresswith a permissioned domain.

In an embodiment, the user can add one or more external source tables toa synchronized table by selecting an external source widget in the userinterface. The user can then pick another source type (e.g. AIRTABLE,SALESFORCE, or JIRA.), select the source table within that type, andthen map the fields from the new source table to the fields in theexisting table. For each column in the target table, the user interfacedisplays a list of columns in the source table, from which the user canselect one column in the source table to associate with the column inthe target table (e.g., such that data from the column in the sourcetable is synchronized to the respective column in the target table).

In some embodiments, when adding a new source, the server 110 tries tomatch column names to existing column names, as described in furtherdetail below. For columns that cannot be matched, the default option maybe to synchronize that data to a new column in the target table instead.The user can change any mappings or opt to synchronize any source columnto a new synchronized column.

In an embodiment, an option to select all columns is not available whenthere are multiple synchronization sources. When the user adds a newsource table, if an existing source table is configured to synchronizeall columns, that source table is changed to synchronize specificcolumns only. The user can use the user interface to alter the fieldmapping by selecting a widget to change mappings. In an embodiment,synchronized target tables that do not synchronize from multiple sourcetables do not include a field mapping. Rather, the target table uses thefields of the source synchronization table.

In an embodiment, after a synchronization is initiated for a targettable from a source table, for every source table field, the user canselect a new target table field in a dropdown of the user interface tochange the target table field associated with the source table field.

Alternatively or additionally, the user can uncheck a field in the userinterface to stop synchronizing data from this source table to themapped target table field, where, if this source table was the primarysource, the synchronized target table column will be destroyed.

Alternatively or additionally, the user can synchronize to a new targettable field, where if the source table field was previously mapped to atarget table field and the source table was the primary source, thesynchronized field may be destroyed, and the data mapped to a new fieldinstead. If the source table was not the primary source, the data may bemapped to a new field. If the source table field was previouslyunmapped, the data in the source table field may be mapped to a newtarget table field.

In an embodiment, the user can reconfigure, using the user interface, aselection of one or more columns to synchronize to a target table from asource table. Alternatively or additionally, the user can reconfigure asynchronization frequency with which the target table synchronizes tothe source table.

Alternatively or additionally, the user can reconfigure whether deletedor hidden rows in the source table are deleted in the target table,where if the user does not choose to delete rows, rows will remain inthe target table even after they are deleted in the source table (theserows can be removed by the user).

Alternatively or additionally, the user can remove a source table, whichremoves all rows associated with the source table. Alternatively oradditionally, the user can turn off synchronization functionality forthe target table, which converts the target table into a normal (e.g.,unsynchronized) data table.

Alternatively or additionally, the user can undo a reconfiguration,which restores the previous set of selected fields, the old synchronizefrequency, the old row deletion setting, and so on; however, theavailability of the fields and the cell values in the fields remains upto date, since the values come from the source table, and as such theyare not reverted to their data from before the reconfiguration.

Alternatively or additionally, the user can trigger a manualsynchronization by clicking a widget of the user interface to initiate asynchronization. The user can do this even when the table is configuredto synchronize automatically. This allows the user to synchronize thetarget table without having to wait for the next scheduledsynchronization.

In an embodiment, removing all synchronizations to source tables from atarget table causes the target table to convert into a normal table thatis not synchronized. No data is removed from the target table, but nofuture changes to source tables are synchronized to the target table.Depending upon the embodiment, this action may not be able to be undone.

In one embodiment, a user can add a button field to the target table andset label text and a color of their choice, where the button links tothe source table. When another user clicks this button, the source tableopens to the corresponding record in the source table in a new tab ofthe user interface (if the other user has access permission). Foranother user that has access to both the source table and target table,the other user can view unsynchronized fields of that source table ormake changes to the source table. If the user has configured the targettable to not delete rows that are hidden or deleted in the source table,the button may be unable to be selected or visually distinguished whenthe source record is hidden or deleted. Depending upon the embodiment,formulas or view filters may consume the output of the button field,e.g., the output of the button field can be a link of the source table'srecord, or null if the source table's record is no longer available.

In one embodiment, if a target table is duplicated, the duplicate tablehas the same configuration as the original target table. If the userdeletes a target table, then restores it, the target table may regainits original configuration from before its deletion.

In an embodiment, the user can change one or more column names ordescriptions of the synchronized portion of the target table. This canbe used to rename columns to be more appropriate for the target table,for example. In an embodiment, when a user hovers over a column icon inthe user interface, they can see the name of the respective source tablecolumn (if the target column has a different name). Depending upon theembodiment, the user may or may not be able to add a row, destroy a row,reconfigure a synchronized column, or edit a cell in a synchronizedcolumn.

The following table illustrates a correspondence of actions taken upon asource table and responsive changes in a target table subsequent to asynchronization, according to one embodiment:

Source table action Target table behavior on next synchronizationDestroy/hide column Destroy column Undestroy/unhide column Undestroycolumn if possible/else create a new column. Add column If ‘synchronizeall fields’ is enabled, add column Add row Row will be added to thetarget table Destroy/hide row If ‘synchronize deletions’ is enabled:destroy row Otherwise: the “open source record” button gets disabledChange cell values Change cell values (based on type conversion) Changefilters The set of visible rows will be synchronized Reorder rows Noimpact Change column configuration to Destroy column unsupportedtype/configuration Change column configuration to Change column config(based on type conversion) supported type/configuration Disablesynchronizing Synchronizing stops working Re-enable synchronizingSynchronizing resumes Delete view Synchronizing stops working Undestroyview Synchronizing resumes Change share URL Synchronizing stops,requires re-authentication Add/change shared view password Synchronizingstops, requires re-authentication Add domain restriction that the userSynchronizing stops, requires re-authentication by a does not satisfyuser in the target table with the appropriate domain

In an embodiment, synchronization may be two-directional between twotables, where each table acts as a source table and a target table, andsynchronized data added to either table is propagated to the other upona subsequent synchronization.

In an embodiment, a user can generate a view-only link to send toanother user, which the other user can use to view the target table only(i.e., the other user cannot edit the target table). Alternatively oradditionally, the user can set a user (e.g., by identifier or emailaddress) or a domain as view-only, where the respective one or moreusers can view but not edit the target table.

In an embodiment, if a field mapping from one source table column to onetarget table column is removed (e.g., by the user), then added back, theserver 110 attempts to restore the same column (thus restoring anylookups that reference that column, or calendars that use it as the datefield, etc.). If the server 110 cannot restore the original column, anew column is created instead.

In an embodiment, if a field of a source table was previouslysynchronized but has since been made unable to be synchronized (e.g., byan administrator of the source table), the user interface may displaythe source table column as visually distinct (e.g., faded out or analternative color) than other source table columns. The user can togglewhether to synchronize currently unavailable fields, though they do notappear when the user toggles them on. Only fields that are currentlyavailable from the source table, along with any currently selected butunavailable fields, appear in the field list.

FIG. 2 illustrates one embodiment of the server 110. In the embodimentshown, the server 110 includes a bases data store 210, a data accessmodule 220, a data update module 230, a data synchronize module 240, anda mapping data store 250. In other embodiments, the server 110 includesdifferent or additional elements. In addition, the functions may bedistributed among the elements in a different manner than described.

The bases data store 210 includes one or more computer-readable mediathat store the one or more databases managed by the server 110. Althoughthe bases data store 210 is shown as a single element within the server110 for convenience, the bases data store 210 may be distributed acrossmultiple computing devices (e.g., as a distributed database). Similarly,individual databases may be hosted by client devices 140 (or othercomputing devices) with the server 110 managing synchronization betweendatabases but not storing the databases themselves.

The data access module 220 provides a mechanism for users to access datain one or more databases. In one embodiment, the data access module 220receives a request from a client device 140 indicating an identifier ofthe requesting user (e.g., a username or user identifier) and data froma specified table in a specified database that the user wishes to view.The data access module 220 determines whether the user has permission toaccess the requested data and, if so, provides it to the client device140 from which the request was received for display to the user.

The data update module 230 provides a mechanism for creators and theircollaborators to edit data in and add data to databases. In oneembodiment, the data update module 230 receives a request from a clientdevice 140 indicating an identifier of the requesting user and data tobe added to or amended into a specified table in a specified database.The data update module 230 determines whether the requesting user haspermission to edit the specified table and, if so, updates the specifiedtable in the bases data store 210 as requested.

The data synchronize module 240 updates some or all portions of targettables to synchronize them with the corresponding source table (ortables). In one embodiment, the data synchronize module 240 periodically(e.g., for a length of time ranging from one second to one hour, such asevery five minutes, every hour, etc.) checks the one or more sourcetables and, if there is updated data available, imports it into thecorresponding one or more target tables (e.g., updates records in thetarget table with respective records from the source table).Additionally or alternatively, users of a target table may force amanual synchronization to one or more source tables (e.g., by selectinga control in the user interface).

The mapping data store 250 includes one or more computer-readable mediathat store tabular data mappings for one or more external servers 115.Although the mapping data store 250 is shown as a single element withinthe server 110 for convenience, the mapping data store 250 may bedistributed across multiple computing devices (e.g., as a distributeddatabase).

A user with suitable permissions to a pair of databases may select asubset of the data in a table in one database (e.g., a source table) tosynchronize with a corresponding table in a second database (e.g., atarget table). Thus, the two tables are referred to as partiallysynchronized, as only a subset of the rows or columns from the sourcetable are used to populate the target table. However, it should be notedthat complete synchronization is also possible, meaning all of thesource table is synchronized with the destination table, and thedestination table has not been enriched with any additional data (thoughit may be, depending upon the embodiment). As described below, a usercan synchronize some or all data from multiple source databases to onetable at one database.

FIG. 3 illustrates the partial synchronization of two tables of twodatabases in the bases data store 210, according to one embodiment. Inthe embodiment shown, the bases data store 210 includes base one 310 andbase two 320. In practice, the bases data store 210 will likely includemany more (e.g., hundreds, thousands, or even millions of) bases. Baseone 310 includes table one 312, which has a synchronized portion 315 andan unsynchronized portion 317. Base two 320 includes table two 322,which includes a synchronized portion 325 (which mirrors thesynchronized portion 315 of table one 312 except for any differencesthat arose since the previous synchronization operation) and an enrichedportion 329. The enriched portion 329 may include data added by users ofbase two 320, data synchronized from a third table, or both.

The third table in such a case may either be another table in base one310 or from a third base (not shown). It should be noted that table two322 is not limited to receiving synchronized data from just two tables.In theory, table two 322 may receive synchronized data from an unlimitednumber of other tables, limited only by computational and memoryrequirements. Similarly, synchronization is not limited to a singlegeneration. Table two 322 may serve as a source table for a thirddestination table, which may in turn serve as a source table for anothertarget table, etc. Furthermore, each synchronization relationshipbetween a source table and a target table may share a different subsetof data selected from either the synchronized portion 325, the enrichedportion 329, or both.

FIG. 4 illustrates multisource synchronization of three tables of threedatabases in the bases data store 210, according to one embodiment. Inthe embodiment shown, the bases data store 210 includes base one 410A,base two 410B, base three 410C, and a field name data store 420. Baseone 410A includes table one 412A, which has a synchronized portion 415Aand an unsynchronized portion 417A. Base two 410B likewise includestable two 412B, which has a synchronized portion 415B and anunsynchronized portion 417B. The field name data store 420 storesmappings between potential field names that have a high likelihood ofbeing synonymous (e.g., “first name” and “given name”). The bases datastore 210 may include additional bases or tables, depending upon theembodiment.

Base three 410C includes table three 412C, which includes a synchronizedportion 425 and an enriched portion 429. The enriched portion 429 mayinclude data added by users of base two 410B, data synchronized from afourth table, or both. For example, the server 110 may receive userinput data (e.g., data that a user input to a client device 140 and sentto the server 110) specifying additional one or more rows or columns toadd to table three 410C.

In this embodiment, table three 412C includes a column 427 thatsynchronizes data from two sources, table one 412A and table two 412B.For example, column 427 includes ten records total, six received fromtable one 412A and four from table two 412B. A user administrating tablethree 412C (e.g., using a client device 140) sets table one 412A as theprimary source. Depending upon the embodiment, the primary source may beautomatically set by the server 110, e.g., based on which source isfirst synchronized to the column 427, or which source provides the mostrecords to the column 427; the automatically set primary source may beupdated by the user, in some embodiments. Source tables other than theprimary source may be considered secondary sources.

The server 110 uses the primary source to determine the data type of thecolumn 427. Data from other sources, e.g., table two 412B, is cast tothe data type of the data from the primary source in the column. Thisresolves ambiguities which may arise from synchronizing columns ofmultiple source tables with different data types to one column in atarget table.

For example, the column synchronized from table one 412A to the column427 may have a data type “text,” where the column synchronized fromtable two 412B to the column 427 may have a data type “date.” Becausetable one 412A is the primary source, the server 110 sets column 427 ashaving data type “text” and casts data from table two 412B for column427 as “text.”

The server 110 may also determine the field configuration for the column427 based on the respective field configuration of the column at theprimary source from which data is synchronized. In one embodiment, theprimary source determines whether the column in the target table isremoved when the source table's column is hidden or destroyed. Forexample, if a column of a primary source is removed from the sourcetable, the server 110 removes the respective column from the targettable, but if the corresponding column is removed from a differentsource table, only records in the target table corresponding to thedifferent source table are affected (e.g., removed). For a target tablewith a single source table, the single source table can be considered tobe the primary source for all fields.

The user also performs field mapping for synchronized fields from tableone 412A and table two 412B to table three 412C. In the field mapping,the user sets a correspondence between a column at each source to acolumn at table three 412C. The server 110 initially attempts to matchfields from sources to table three 412C according to field name, whichthe user can override via a user interface. The server 110 comparesfield names from synchronized columns of a source (e.g., table one 412A)to field names of synchronized columns in the target table (e.g., tablethree 412C) and, upon identifying a matching pair, maps the source fieldto the target field.

For example, table one 412A may include a “first name” field and a “lastname” field, table two 412B may include a “given name” field, a “middlename” field, and a “surname” field, and table three 412C may include a“first name” field and a “family name” field. The server 110 matches the“first name” field from table one 412A to the “first name” field fromtable three 412C, indicating that data from the “first name” field oftable one 412A will synchronize to the “first name” field of table three412C. The user maps the “given name” field of table two 412B to the“first name” field of table three 412C, and the “last name” field oftable one 412A and the “surname” field of table two 412B to the “familyname” field of table three 412C. As such, data from table one 412 A andtable 412B will synchronize to the mapped fields in table three 412C.

In an embodiment, the server 110 auto-matches columns with synonymousfield names, as determined according to the field name data store 420.The field name data includes mappings between field names that arelikely to be synonymous. Thus, the server 110 can use the field namedata to identify columns with different but synonymous names as likelymatches. The matches can be automatically applied or presented to theuser as suggestions for verification.

EXAMPLE METHODS

FIG. 5 illustrates a method 500 for partially synchronizing databasetables, according to one embodiment. The steps of FIG. 5 are illustratedfrom the perspective of the server 110 performing the method 500.However, some or all of the steps may be performed by other entities orcomponents. In addition, some embodiments may perform the steps inparallel, perform the steps in different orders, or perform differentsteps.

In the embodiment shown in FIG. 5, the method 500 begins with the server110 configuring 505 a periodic synchronization between a first databaseand a second database. This may be prompted by the server 110 receivinga request to do so. The server 110 receives 510 a request to update afirst table in a first database. The server 110 updates 520 the firsttable as requested. As part of a synchronization operation (eitherperiodic or manually triggered), the server 110 imports 530 a portion ofthe updated first table into a corresponding portion of a second tablein a second database. Depending upon the embodiment, the portion of theupdated first table imported 530 to the second table may include onlythe subset of data of the updated first table that has changed since aprevious synchronization operation, or the portion may include all datadesignated for synchronization from the first table to the second table.The server 110 also enriches 540 the second table with additional datawithout impacting the first table. As described previously, theadditional data may be imported from another table, entered by a user ofthe second database, or both.

FIG. 6 illustrates a method 600 for multisource synchronizing databasetables, according to one embodiment. The steps of FIG. 6 are illustratedfrom the perspective of the server 110 performing the method 600.However, some or all of the steps may be performed by other entities orcomponents. In addition, some embodiments may perform the steps inparallel, perform the steps in different orders, or perform differentsteps.

In the embodiment shown in FIG. 6, the method 600 begins with the server110 receiving 610 a request to add a second source to a first table in afirst database that synchronizes data from a first source. The server110 receives 620 a designation of the second source as a primary source.As such, data from the first source that is synchronized to portions ofthe first table where data from the second source also syncs will becast to the data type of the data received from the second source forthat portion and configured according to a field configuration of thedata received from the second source for that portion. The server 110imports 630 data from the first source and the second source to thefirst table, where data from the first source is cast to the typespecified by the second source.

Computing System Architecture

FIG. 7 is a block diagram illustrating an example computer 700 suitablefor use as the server 110 or a client device 140. The example computer700 includes at least one processor 702 coupled to a chipset 704. Thechipset 704 includes a memory controller hub 720 and an input/output(I/O) controller hub 722. A memory 706 and a graphics adapter 712 arecoupled to the memory controller hub 720, and a display 718 is coupledto the graphics adapter 712. A storage device 708, keyboard 710,pointing device 714, and network adapter 716 are coupled to the I/Ocontroller hub 722. Other embodiments of the computer 700 have differentarchitectures.

In the embodiment shown in FIG. 7, the storage device 708 is anon-transitory computer-readable storage medium such as a hard drive,compact disk read-only memory (CD-ROM), DVD, or a solid-state memorydevice. The memory 706 holds instructions and data used by the processor702. The pointing device 714 is a mouse, track ball, touchscreen, orother type of pointing device, and is used in combination with thekeyboard 710 (which may be an on-screen keyboard) to input data into thecomputer system 700. The graphics adapter 712 displays images and otherinformation on the display 718. The network adapter 716 couples thecomputer system 700 to one or more computer networks.

The types of computers used by the entities of FIGS. 1 through 4 canvary depending upon the embodiment and the processing power required bythe entity. For example, the server 110 might include a distributeddatabase system comprising multiple blade servers working together toprovide the functionality described. Furthermore, the computers can lacksome of the components described above, such as keyboards 710, graphicsadapters 712, and displays 718.

Additional Considerations

In various embodiments, aggregated synchronization can also be referredto as multi-source synchronization.

Some portions of above description describe the embodiments in terms ofalgorithmic processes or operations. These algorithmic descriptions andrepresentations are commonly used by those skilled in the computing artsto convey the substance of their work effectively to others skilled inthe art. These operations, while described functionally,computationally, or logically, are understood to be implemented bycomputer programs comprising instructions for execution by a processoror equivalent electrical circuits, microcode, or the like. Furthermore,it has also proven convenient at times, to refer to these arrangementsof functional operations as modules, without loss of generality.

As used herein, any reference to “one embodiment” or “an embodiment”means that a particular element, feature, structure, or characteristicdescribed in connection with the embodiment is included in at least oneembodiment. The appearances of the phrase “in one embodiment” in variousplaces in the specification are not necessarily all referring to thesame embodiment. Similarly, use of “a” or “an” preceding an element orcomponent is done merely for convenience. This description should beunderstood to mean that one or more of the elements or components arepresent unless it is obvious that it is meant otherwise.

Where values are described as “approximate” or “substantially” (or theirderivatives), such values should be construed as accurate +/−10% unlessanother meaning is apparent from the context. From example,“approximately ten” should be understood to mean “in a range from nineto eleven.”

As used herein, the terms “comprises,” “comprising,” “includes,”“including,” “has,” “having” or any other variation thereof, areintended to cover a non-exclusive inclusion. For example, a process,method, article, or apparatus that comprises a list of elements is notnecessarily limited to only those elements but may include otherelements not expressly listed or inherent to such process, method,article, or apparatus. Further, unless expressly stated to the contrary,“or” refers to an inclusive or and not to an exclusive or. For example,a condition A or B is satisfied by any one of the following: A is true(or present) and B is false (or not present), A is false (or notpresent) and B is true (or present), and both A and B are true (orpresent).

Upon reading this disclosure, those of skill in the art will appreciatestill additional alternative structural and functional designs for asystem and a process for providing partial synchronization of databasetables. Thus, while particular embodiments and applications have beenillustrated and described, it is to be understood that the describedsubject matter is not limited to the precise construction and componentsdisclosed. The scope of protection should be limited only by thefollowing claims.

What is claimed is:
 1. A computer-implemented method for datasynchronization, comprising: receiving, by a computing device, a requestto synchronize a first set of data from a first base and a second set ofdata from a second base to a third base, each of the first base and thesecond base having data arranged in rows and columns; setting, by thecomputing device, the first base as a primary source; casting, by thecomputing device, a data type of a particular column in the third basethat includes data from both the first base and the second base, as adata type of the primary source; casting, by the computing device, afield configuration of the particular column in the third base as afield configuration of the primary source; configuring, by the computingdevice, a periodic synchronization from the first base to the third baseand from the second base to the third base; and periodicallysynchronizing, by the computing device, the first set of data from thefirst base to the third base and the second set of data from the secondbase to the third base.
 2. The computer-implemented method of claim 1,further comprising: receiving, by the computing device, a request tosynchronize a third set of data from the third base to a fourth base,wherein the third set of data comprises at least a portion of the firstset of data and at least a portion of the second set of data; andconfiguring, by the computing device, a periodic synchronization of thethird set of data from the third base to the fourth base.
 3. Thecomputer-implemented method of claim 1, wherein a period of the periodicsynchronization is a length of time ranging from one second to one hour.4. The computer-implemented method of claim 1, wherein the first base isat an external computing device, the method further comprising:identifying, by the computing device, the external computing device;fetching, by the computing device, a tabular data mapping for theexternal computing device; and synchronizing, by the computing device,data from the external computing device using the tabular data mapping.5. The computer-implemented method of claim 1, further comprising:receiving, by the computing device, from a user associated with thethird base, a new set of data to add to the third base; and adding, bythe computing device, the new set of data to the third base, whereinneither the first base nor the second base includes the new set of data.6. The computer-implemented method of claim 1, wherein the third basecomprises, in association with a record from the first set of data, abutton, the method further comprising: receiving, by the computingdevice, a selection of the button; and responsive to receiving theselection of the button, opening, by the computing device, a view of thefirst base.
 7. The computer-implemented method of claim 1, wherein thefirst base is access-limited to a first set of users, the second base isaccess-limited to a second set of users, and the third base isaccess-limited to a third set of users, wherein the third set of userscomprises at least one user not in the first set of users and not in thesecond set of users.
 8. The computer-implemented method of claim 1,wherein configuring, by the computing device, the periodicsynchronization of the first set of data from the first base to thethird base, comprises: receiving, by the computing device, a first fieldmapping of columns in the first base to columns in the third base,wherein data in a column of the first base is periodically propagated toa mapped column in the third base.
 9. The computer-implemented method ofclaim 8, wherein configuring, by the computing device, the periodicsynchronization of the second set of data from the second base to thethird base, comprises: receiving, by the computing device, a secondfield mapping of columns in the second base to columns in the thirdbase, wherein data in a column of the second base is periodicallypropagated to a mapped column in the third base; and wherein a specificcolumn in the first base mapped in the first field mapping to a specificcolumn in the third base comprises a different name than a specificcolumn in the second base mapped in the second field mapping to thespecific column in the third base.
 10. The computer-implemented methodof claim 8, wherein configuring, by the computing device, the periodicsynchronization of the second set of data from the second base to thethird base, comprises: receiving, by the computing device, an edit tothe first field mapping for a certain column of the first base thatalters which column of the third base to which the certain column of thefirst base maps.
 11. The computer-implemented method of claim 1, whereinconfiguring, by the computing device, the periodic synchronization ofthe first set of data from the first base to the third base, comprises:determining, by the computing device, a field mapping of columns in thefirst base to columns in the third base, wherein data in a column of thefirst base is periodically propagated to a mapped column in the thirdbase.
 12. The computer-implemented method of claim 11, whereindetermining the field mapping comprises: matching, by the computingdevice, a name of the column in the first base to a name of the mappedcolumn in the third base.
 13. The computer-implemented method of claim12, wherein matching the name of the column in the first base to thename of the mapped column in the third base comprises: referencing afield name data store comprising one or more mappings of synonymouscolumn names to each other.
 14. The computer-implemented method of claim1, further comprising: receiving, by the computing device, a request toend the periodic synchronization of the first base to the third base;and terminating, by the computing device, the periodic synchronizationof the first base to the third base, wherein the third base retains itsdata as of a most recent instance of the periodic synchronization fromthe first base, and wherein the periodic synchronization from the secondbase to the third base is not terminated in response to the request toend the periodic synchronization from the first base to the third base.15. The computer-implemented method of claim 1, wherein the first set ofdata comprises a first set of columns set as available, the methodfurther comprising: determining, by the computing device, that a userassociated with the first base has marked a particular column of thefirst set of columns as unavailable; and responsive to the particularcolumn of the first set of columns being marked as unavailable,periodically synchronizing, by the computing device, the first set ofdata, excluding the particular column, from the first base to the thirdbase.
 16. The computer-implemented method of claim 1, wherein the firstset of data comprises a first set of columns, the method furthercomprising: determining, by the computing device, that a particularcolumn in the first set of columns has been removed from the first setof columns, wherein the particular column in the first set of columns ismapped to a particular column in the third base; periodicallysynchronizing, by the computing device, the first set of columns,excluding the particular column in the first set of columns, from thefirst base to the third base; determining, by the computing device, thatthe particular column in the first set of columns is added to the firstset of columns; determining, by the computing device, that theparticular column in the first set of columns cannot synchronize to theparticular column in the third base to which it was mapped; andsynchronizing, by the computing device, the first set of columns,including the particular column in the first set of columns, from thefirst base to the third base, wherein the particular column in the firstset of columns is synchronized to a new column in the third base. 17.The computer-implemented method of claim 1, further comprising:determining, by the computing device, that a record in the first set ofdata previously synchronized to the third base is no longer in the firstset of data as of a most recent periodic synchronization; and deleting,by the computing device, the record from the third base.
 18. Acomputer-implemented method for data synchronization, comprising:receiving, by a computing device, a request to synchronize a first setof data from a first base and a second set of data from a second base toa third base, each of the first base and the second base having dataarranged in rows and columns, and the first base is at an externalcomputing device; identifying, by the computing device, the externalcomputing device; setting, by the computing device, the first base as aprimary source; fetching, by the computing device, a tabular datamapping for the external computing device; casting, by the computingdevice, a data type of a particular column in the third base thatincludes data from both the first base and the second base, as a datatype of the primary source; configuring, by the computing device, aperiodic synchronization from the first base to the third base and fromthe second base to the third base; and periodically synchronizing, bythe computing device, the first set of data from the first base to thethird base and the second set of data from the second base to the thirdbase, using the tabular data mapping.
 19. The computer-implementedmethod of claim 18, wherein configuring, by the computing device, theperiodic synchronization of the first set of data from the first base tothe third base, comprises: receiving, by the computing device, a firstfield mapping of columns in the first base to columns in the third base,wherein data in a column of the first base is periodically propagated toa mapped column in the third base.
 20. A non-transitorycomputer-readable storage medium storing computer program instructionsexecutable by one or more processors of a computing device, the computerprogram instructions comprising computer program instructions of thecomputing device to: receive, by the computing device, a request tosynchronize a first set of data from a first base and a second set ofdata from a second base to a third base, each of the first base and thesecond base having data arranged in rows and columns; set, by thecomputing device, the first base as a primary source; cast, by thecomputing device, a data type of a particular column in the third basethat includes data from both the first base and the second base, as adata type of the primary source; cast, by the computing device, a fieldconfiguration of the particular column in the third base as a fieldconfiguration of the primary source; configure, by the computing device,a periodic synchronization from the first base to the third base andfrom the second base to the third base; and periodically synchronize, bythe computing device, the first set of data from the first base to thethird base and the second set of data from the second base to the thirdbase.